CN107532315A - Amberplex - Google Patents
Amberplex Download PDFInfo
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- CN107532315A CN107532315A CN201680022563.8A CN201680022563A CN107532315A CN 107532315 A CN107532315 A CN 107532315A CN 201680022563 A CN201680022563 A CN 201680022563A CN 107532315 A CN107532315 A CN 107532315A
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- layer
- electrolysis
- amberplex
- fluoropolymer
- ion
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- B01J39/00—Cation exchange; Use of material as cation exchangers; Treatment of material for improving the cation exchange properties
- B01J39/08—Use of material as cation exchangers; Treatment of material for improving the cation exchange properties
- B01J39/16—Organic material
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- B01J39/00—Cation exchange; Use of material as cation exchangers; Treatment of material for improving the cation exchange properties
- B01J39/08—Use of material as cation exchangers; Treatment of material for improving the cation exchange properties
- B01J39/16—Organic material
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- B01J47/00—Ion-exchange processes in general; Apparatus therefor
- B01J47/12—Ion-exchange processes in general; Apparatus therefor characterised by the use of ion-exchange material in the form of ribbons, filaments, fibres or sheets, e.g. membranes
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- B32B27/00—Layered products comprising a layer of synthetic resin
- B32B27/06—Layered products comprising a layer of synthetic resin as the main or only constituent of a layer, which is next to another layer of the same or of a different material
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- C08F16/00—Homopolymers and copolymers of compounds having one or more unsaturated aliphatic radicals, each having only one carbon-to-carbon double bond, and at least one being terminated by an alcohol, ether, aldehydo, ketonic, acetal or ketal radical
- C08F16/12—Homopolymers and copolymers of compounds having one or more unsaturated aliphatic radicals, each having only one carbon-to-carbon double bond, and at least one being terminated by an alcohol, ether, aldehydo, ketonic, acetal or ketal radical by an ether radical
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- C08J5/2243—Synthetic macromolecular compounds based on macromolecular compounds obtained by reactions involving unsaturated carbon-to-carbon bonds obtained by introduction of active groups capable of ion-exchange into compounds of the type C08J5/2231
- C08J5/225—Synthetic macromolecular compounds based on macromolecular compounds obtained by reactions involving unsaturated carbon-to-carbon bonds obtained by introduction of active groups capable of ion-exchange into compounds of the type C08J5/2231 containing fluorine
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- C08L27/02—Compositions of homopolymers or copolymers of compounds having one or more unsaturated aliphatic radicals, each having only one carbon-to-carbon double bond, and at least one being terminated by a halogen; Compositions of derivatives of such polymers not modified by chemical after-treatment
- C08L27/12—Compositions of homopolymers or copolymers of compounds having one or more unsaturated aliphatic radicals, each having only one carbon-to-carbon double bond, and at least one being terminated by a halogen; Compositions of derivatives of such polymers not modified by chemical after-treatment containing fluorine atoms
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- C25B1/00—Electrolytic production of inorganic compounds or non-metals
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- C25B1/34—Simultaneous production of alkali metal hydroxides and chlorine, oxyacids or salts of chlorine, e.g. by chlor-alkali electrolysis
- C25B1/46—Simultaneous production of alkali metal hydroxides and chlorine, oxyacids or salts of chlorine, e.g. by chlor-alkali electrolysis in diaphragm cells
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Abstract
The amberplex of the present invention has comprising the layer A with the sulfonic fluoropolymer and layer B comprising the fluoropolymer with carboxylic acid group, and the ion cluster footpath of the above-mentioned layer B after being electrolysed under following electrolytic conditions is 0.83~0.95 relative to the ratio [(the ion cluster footpath of the layer B after above-mentioned electrolysis)/(the ion cluster footpath of the layer B before above-mentioned electrolysis)] in the ion cluster footpath of the above-mentioned layer B before above-mentioned electrolysis.Electrolytic condition is:In zero polar distance electrolytic bath, temperature be 85 DEG C, current density 6kA/m2Under conditions of carry out 7 days be electrolysed, in zero polar distance electrolytic bath, be fed with the anode chamber of sodium-chloride water solution of 3.5 equivalents (N) and be fed with 10.8 equivalents (N) sodium hydrate aqueous solution cathode chamber between be configured with above-mentioned amberplex.
Description
Technical field
The present invention relates to amberplex.
Background technology
The heat resistance of exchange membrane containing fluorine and chemical proofing etc. are excellent, are used as alkali chloride electrolysis, be smelly
Oxygen produce electrolysis with, fuel cell with, water electrolysis with, electrolysis of hydrochloric acid with etc. electrolysis be used for barrier film in various uses.
Among them, particularly in the electrolysis of manufacture chlorine and the alkali metal chloride of alkali metal hydroxide, in recent years
Ion exchange membrane turns into main flow.For the various performances of amberplex requirement used in the electrolysis of alkali metal chloride.Example
Such as require following performances:It can carry out containing in electrolysis and manufactured alkali metal hydroxide with high current efficiency and low decomposition voltage
The concentration of some impurity (particularly alkali metal chloride etc.) is low to wait electrolysis performance;And film-strength is high, film process when or electrolysis
The film-strengths such as damage occur for Shi Buhui;Etc..Also, the electrolysis performance of amberplex is in shifting pass with film-strength
System, it is desirable to develop two kinds of high amberplexes of performance.
Patent Document 1 discloses a kind of amberplex, its by with sulfonic fluoropolymer layer and with
At least two layers composition of the fluoropolymer layer of carboxylic acid group.
Prior art literature
Patent document
Patent document 1:Japanese Unexamined Patent Publication 2001-323084 publications
The content of the invention
Invent problem to be solved
But the amberplex described in patent document 1 take into account film-strength and electrolysis aspect of performance it is also further
Room for improvement.
The present invention be in view of problem present in above-mentioned prior art and carry out, its object is to provide film-strength and electricity
Solve the excellent amberplex of performance these two aspects.
The means to solve the problem
The present inventor has made intensive studies to solve above-mentioned problem, as a result finds, by making amberplex internal memory
Ion cluster shunk in electrolysis, subtract according to the ion cluster footpath after electrolysis with ion-exchange film relative to the ion cluster footpath before electrolysis
The small mode for defined ratio is controlled, and electrolysis performance improves tremendously, so as to complete the present invention.
That is, the present invention is as described below.
[1]
A kind of amberplex, it has:
Comprising the layer A with sulfonic fluoropolymer and
Layer B comprising the fluoropolymer with carboxylic acid group,
Following electrolytic conditions electrolysis after above-mentioned layer B ion cluster footpath relative to the above-mentioned layer B before above-mentioned electrolysis from
The ratio between submanifold footpath [(the ion cluster footpath of the layer B after above-mentioned electrolysis)/(the ion cluster footpath of the layer B before above-mentioned electrolysis)] be 0.83~
0.95。
(electrolytic condition)
In zero polar distance electrolytic bath, temperature be 85 DEG C, current density 6kA/m2Under conditions of carry out 7 days be electrolysed, institute
State in zero polar distance electrolytic bath, be fed with the anode chamber of the sodium-chloride water solution of 3.5 equivalents (N) and be fed with 10.8 equivalents (N)
Sodium hydrate aqueous solution cathode chamber between be configured with above-mentioned amberplex.
[2]
Such as the amberplex described in [1], wherein,
The ion cluster footpath of layer B before above-mentioned electrolysis is 2.5nm~4.0nm,
The ion cluster footpath of layer B after above-mentioned electrolysis is 2.0nm~3.3nm.
[3]
Such as the amberplex described in [1] or [2], wherein, before above-mentioned electrolysis, above-mentioned layer A thickness and above-mentioned layer B
Thickness add up to more than 55 μm.
[4]
Such as the amberplex any one of [1]~[3], wherein, the ion cluster footpath of the layer A before above-mentioned electrolysis is
3.0nm~4.5nm.
[5]
Such as the amberplex any one of [1]~[4], wherein,
The thickness of layer A before above-mentioned electrolysis is 50 μm~180 μm,
The thickness of layer B before above-mentioned electrolysis is 5 μm~20 μm.
[6]
Such as the amberplex any one of [1]~[5], wherein,
Above-mentioned layer A includes the polymer of the compound represented by following formula (2),
Above-mentioned layer B includes the polymer of the compound represented by following formula (3),
CF2=CF- (OCF2CYF)a-O-(CF2)b-SO2F (2)
(in formula (2), a represents 0~2 integer, and b represents 1~4 integer, Y expression-F or-CF3。)
CF2=CF- (OCF2CYF)c-O-(CF2)d-COOR (3)
(in formula (3), c represents 0~2 integer, and d represents 1~4 integer, Y expression-F or-CF3, R expressions-CH3、-C2H5
Or-C3H7。)
[7]
A kind of electrolytic cell, it possesses the amberplex any one of [1]~[6].
The effect of invention
The film-strength and electrolysis excellent performance of the amberplex of the present invention.
Brief description of the drawings
Fig. 1 is the schematic sectional view of one of the amberplex of present embodiment.
Fig. 2 is the schematic diagram of one of the electrolytic cell of present embodiment.
Embodiment
The embodiment (hereinafter referred to as " present embodiment ") of the present invention is described in detail below.Need to illustrate
, it is of the invention to be not limited to following present embodiment, various modifications can be carried out in the range of its main points to implement.
The amberplex of present embodiment has:Comprising the layer A with sulfonic fluoropolymer (below sometimes
Be abbreviated as " layer A ") and layer B (be also abbreviated as sometimes below " layer B ") comprising the fluoropolymer with carboxylic acid group, under
The ion cluster footpath of the above-mentioned layer B after electrolytic condition (1) electrolysis is stated relative to the ratio between above-mentioned layer B ion cluster footpath before above-mentioned electrolysis
[(the ion cluster footpath of the layer B after electrolysis)/(the ion cluster footpath of the layer B before electrolysis)] is 0.83~0.95.Herein, electrolytic condition
(1) be, in zero polar distance electrolytic bath, temperature be 85 DEG C, current density 6kA/m2Under conditions of carry out 7 days be electrolysed, it is described
In zero polar distance electrolytic bath, it is being fed with the anode chamber of the sodium-chloride water solution of 3.5 equivalents (N) and is being fed with 10.8 equivalents (N)
Amberplex is configured between the cathode chamber of sodium hydrate aqueous solution.Formed due to like this, thus present embodiment
The film-strength and electrolysis excellent performance of amberplex.The electrolysis that above-mentioned electrolytic condition (1) will be also based on below is referred to as " electricity
Solution ".It should be noted that in this manual, " zero pole span " refers to, and in electrolyte layers, amberplex and negative electrode and anode
(the distance between amberplex and anode and the distance between amberplex and negative electrode are zero for state that this two side connects
State), these parts can be the state that connects with amberplex of whole surface in electrode (male or female), also may be used
Think the state to connect in the certain point of electrode surface with amberplex.
Fig. 1 shows the schematic sectional view of one of the composition of the amberplex of present embodiment.Present embodiment
In amberplex, comprising the layer A (4) with sulfonic fluoropolymer and the fluoropolymer with carboxylic acid group is included
Layer B (5) has carried out lamination, has enhancing core 3 and intercommunicating pore 2a and 2b inside film.Generally according to comprising with sulfonic group
Fluoropolymer layer A (4) be the anode-side (α) of electrolytic cell, the layer B (5) comprising the fluoropolymer with carboxylic acid group be
The mode of the cathode side (β) of electrolytic cell is configured.In addition, there is coating layer 6 and 7 on film surface.In Fig. 1, intercommunicating pore 2a
Formed with enhancing core 3 relative to the vertical direction of paper, intercommunicating pore 2b is formed in the above-below direction of paper.That is, in paper
Above-below direction formed intercommunicating pore 2b along relative to enhancing the generally perpendicular direction of core 3 formed.In addition, intercommunicating pore 2a and
2b can also the position 8 with facing layer A anode-side surface.As shown in figure 1, the amberplex of present embodiment is preferably pressed
The mode to connect according to layer A surface with layer B surface carries out lamination.Layer A and layer B are combined referred to as film master sometimes below
Body.
[layer A]
Layer A contained by the amberplex of present embodiment, which is included, has sulfonic fluoropolymer A (below sometimes
Be abbreviated as " polymer A "), preferably formed by polymer A.Herein, refer to " with sulfonic fluoropolymer " with sulfonic acid
Base can be by hydrolyzing to form the fluoropolymer of sulfonic sulfonic acid based precursor.It should be noted that in layer A, except
Beyond polymer A, it can also be gathered with including polymer B described later relative to scopes of the 100 mass % layers A less than 20 mass %
Compound A is preferably comprised more than 80 mass % relative to 100 mass % layers A.
Form layer A has sulfonic fluoropolymer A for example can be by by following 1st group of monomers and the 2nd group of monomer
It is copolymerized or manufactures the 2nd group of monomer homopolymerization.Polymer A be copolymer in the case of, its can be block polymer,
It can be atactic polymer.
It is not particularly limited as the 1st group of monomer, such as fluorinated vinylether compound can be enumerated.
As fluorinated vinylether compound, the compound preferably represented by following formulas (1).
CF2=CX1X2 (1)
(in formula (1), X1And X2Expression-F ,-Cl ,-H or-CF independently of one another3。)
It is not particularly limited as the fluorinated vinylether compound represented by above-mentioned formula (1), such as fluorination second can be enumerated
Alkene, tetrafluoroethene, hexafluoropropene, vinylidene fluoride, trifluoro-ethylene, CTFE etc..
Particularly in the case where the amberplex of present embodiment is used as into alkaline electrolysis film, ethylene fluoride chemical combination
Thing is preferably perfluorinated monomers, more preferably the perfluorinated monomers in the group being made up of tetrafluoroethene, hexafluoropropene, further excellent
Elect tetrafluoroethene (TFE) as.
1st group of monomer can be used alone, and can also share two or more.
It is not particularly limited, such as can be enumerated with sulfonic acid type ion exchange base can be converted into as the 2nd group of monomer
Functional group vinyl compound.
As the vinyl compound with the functional group that can be converted into sulfonic acid type ion exchange base, preferably by following logical
The compound that formula (2) represents.
CF2=CF- (OCF2CYF)a-O-(CF2)b-SO2F (2)
(in formula (2), a represents 0~2 integer, and b represents 1~4 integer, Y expression-F or-CF3。)
In formula (2), when a is 2, a plurality of existing Y are separate.
It is not particularly limited as the 2nd group of monomer, such as monomer as shown below etc. can be enumerated:
CF2=CFOCF2CF2SO2F、
CF2=CFOCF2CF(CF3)OCF2CF2SO2F、
CF2=CFOCF2CF(CF3)OCF2CF2CF2SO2F、
CF2=CF (CF2)2SO2F、
CF2=CFO [CF2CF(CF3)O]2CF2CF2SO2F、
CF2=CFOCF2CF(CF2OCF3)OCF2CF2SO2F。
Among them, preferably CF2=CFOCF2CF(CF3)OCF2CF2CF2SO2F and CF2=CFOCF2CF(CF3)
OCF2CF2SO2F。
2nd group of monomer can be used alone, and can also share two or more.
Species, its ratio and degree of polymerization of combination of monomer to forming polymer A etc. are not particularly limited.In addition, layer A
In contained polymer A can be individually it is a kind of, can also be two or more combinations.In addition, with sulfonic fluorine-containing
Polymer A ion exchange capacity can be by being changed to adjust by the ratio between monomer represented by above-mentioned formula (1) and (2)
It is whole.
Layer A can be individual layer, can also be formed by more than 2 layers according to the polymer A formed composition.
In the case that layer A is individual layer, its thickness is preferably less than more than 50 μm 180 μm, more preferably more than 80 μm 160 μm
Below.Layer A thickness within that range when, the intensity of film main body is tended to further increase.
In this manual, in the case where layer A is 2 Rotating fields, using the layer for the side that connects with anode as layer A-1, incite somebody to action
Connect with layer B side layer as fluoropolymer layer A-2.Herein, forming layer A-1 fluoropolymer is (also referred to as " fluorine-containing poly-
Compound A-1 ") from forming layer A-2 fluoropolymer (also referred to as " fluoropolymer A-2 ") it is preferably to form different polymerizations
Thing.Layer A-1 thickness is preferably less than more than 10 μm 60 μm.Layer A-2 thickness be preferably less than more than 30 μm 120 μm, it is more excellent
Elect less than more than 40 μm 100 μm as.Layer A-1 and layer A-2 thickness within the above range when, film main body can be substantially ensured that
Intensity.In addition, the total of layer A-1 and layer A-2 thickness is preferably less than more than 50 μm 180 μm, more preferably more than 80 μm 160
Below μm., can be by the film layer of more than 2 formed by forming different polymer A in the case that layer A is formed by more than 2 layers
Accumulate and forming layer A.
[layer B]
Layer B contained by the amberplex of present embodiment includes the fluoropolymer B with carboxylic acid group (below sometimes
It is abbreviated as " polymer B ").Herein, " fluoropolymer with carboxylic acid group " refers to carboxylic acid group or can be by hydrolyzing shape
Into the fluoropolymer of the carboxylic acid based precursor of carboxylic acid group.It should be noted that in layer B, can be with relative to 100 mass % layers
Scopes of the B less than 10 mass % includes the composition beyond polymer B, and polymer B preferably comprises 90 relative to 100 mass % layers B
More than quality %, polymer B particularly preferably include 100 mass %.It should be noted that as in layer B in addition to polymer B
The composition that can be included, it can enumerate but be not limited to such as the metal chloride of potassium chloride etc.
Forming the layer B fluorine-containing based polymer with carboxylic acid group for example can be by by above-mentioned 1st group of monomer and following 3
Group monomer copolymerization manufactures the 3rd group of monomer homopolymerization.In the case where polymer B is copolymer, it can be block copolymerization
Thing, can also be atactic polymer.
It is not particularly limited, such as can be enumerated with carboxylic acid type ion-exchange group can be converted into as the 3rd group of monomer
Functional group vinyl compound.
As the vinyl compound with the functional group that can be converted into carboxylic acid type ion-exchange group, preferably by following logical
The compound that formula (3) represents.
CF2=CF- (OCF2CYF)c-O-(CF2)d-COOR (3)
(in formula (3), c represents 0~2 integer, and d represents 1~4 integer, Y expression-F or-CF3, R expressions-CH3、-
C2H5Or-C3H7。)
In formula (3), when c is 2, a plurality of existing Y are separate.In above-mentioned formula (3), preferably Y is-CF3, R for-
CH3。
Particularly in the case where the amberplex of present embodiment is used as into alkaline electrolysis amberplex, as
3rd group of monomer preferably at least uses perfluorinated monomers.But the alkyl (with reference to above-mentioned R) in ester group at the time of hydrolysis from polymer
Lose, therefore alkyl (R) may not be perfluoroalkyl.Among them, it is not particularly limited as the 3rd group of monomer, such as more
It is preferred that monomer as shown below:
CF2=CFOCF2CF(CF3)OCF2COOCH3、
CF2=CFOCF2CF(CF3)O(CF2)2COOCH3、
CF2=CF [OCF2CF(CF3)]2O(CF2)2COOCH3、
CF2=CFOCF2CF(CF3)O(CF2)3COOCH3、
CF2=CFO (CF2)2COOCH3、
CF2=CFO (CF2)3COOCH3。
3rd group of monomer can be used alone, can also be shared two or more.
Species, its ratio and degree of polymerization of combination of monomer to forming polymer B etc. are not particularly limited.In addition, layer B
In contained polymer B can be individually it is a kind of, can also be two or more combinations.In addition, with the fluorine-containing of carboxylic acid group
The ion exchange capacity of polymer B can be by being changed to adjust by the ratio between monomer represented by above-mentioned formula (3) and (4)
It is whole.
As layer B thickness, preferably less than more than 5 μm 50 μm, more preferably less than more than 5 μm 20 μm.Layer B thickness
When within that range, the electrolysis performance of amberplex is tended to further improve, and height can further be reached by as a result having
The tendency of current efficiency and low-voltage.In addition, when layer B film thickness is in above-mentioned scope, it is easy in electrolysis middle level B cluster
Shrink, the value in [(the ion cluster footpath of the layer B after electrolysis)/(the ion cluster footpath of the layer B before electrolysis)] easily reduces.
In the amberplex of present embodiment, from the aspect of further raising electrolysis performance and intensity, preferably
Polymer and layer B that layer A includes the compound represented by above-mentioned formula (2) include the polymerization of the compound represented by above-mentioned formula (3)
Thing.
In the amberplex of present embodiment, before electrolysis, layer A thickness is total excellent with above-mentioned layer B thickness
Elect more than 55 μm, more preferably less than more than 55 μm 210 μm, more preferably less than more than 85 μm 190 μm as.By making layer
A and layer B thickness it is total within that range, the intensity of film main body is tended to further improve.From same aspect,
It is preferred that the thickness of the layer A before electrolysis is 50 μm~180 μm and the layer B thickness before being electrolysed is 5 μm~30 μm.Herein, layer A
After referring to experienced hydrolyzing process described later with the respective thickness of layer B, form before above-mentioned electrolysis amberplex layer A and
Layer B respective thickness, is measured using the method described in embodiment.In addition, above-mentioned thickness can for example pass through regulation
The extrusion capacity of aftermentioned membranization process and the hauling speed of film are controlled.
[the ratio between front and rear ion cluster footpath of electrolysis]
Ion cluster be present under saturation state in the amberplex of present embodiment.Ion cluster is the space that ion passes through,
Formed by the association of ion-exchange group.Ion cluster footpath with the associating intensity of ion-exchange group and the moisture content of film main body and
Change, it can be controlled by the ion exchange capacity of fluoropolymer and the condition of hydrolysis, in addition, cluster footpath is sometimes due to logical
Electricity and change.The amberplex of present embodiment is due to being electrolysed the ratio between front and rear ion cluster footpath in defined scope
Interior, the film-strength and electrolysis both performances of amberplex are excellent.
In the amberplex of present embodiment, when electrolytic condition (1) is electrolysed, [(layer B after electrolysis from
Submanifold footpath)/(the ion cluster footpath of the layer B before electrolysis)] for 0.83~0.95, be preferably 0.83~0.92, more preferably 0.83~
0.90.Herein, electrolytic condition (1) is following conditions:The amberplex is configured between anode chamber and cathode chamber, to above-mentioned sun
3.5 equivalents (N) sodium-chloride water solution is supplied in pole room, the sodium hydroxide water of 10.8 equivalents (N) is supplied into above-mentioned cathode chamber
Solution, electrolysis temperature be 85 DEG C, current density 6kA/m2Under conditions of carry out 7 days be electrolysed.Herein, " layer B's before electrolysis
Ion cluster footpath " refers to after hydrolyzing process in the manufacture of amberplex described later and the ion before for electrolysis
The ion cluster footpath of layer B in exchange membrane." the ion cluster footpath of the layer B after electrolysis " refers to be electrolysed in above-mentioned electrolytic condition (1)
The ion cluster footpath of layer B in amberplex afterwards.It should be noted that in this manual, sometimes also will be [(after electrolysis
Layer B ion cluster footpath)/(the ion cluster footpath of the layer B before electrolysis)] be abbreviated as the ratio between " electrolysis front and rear layer B ion cluster footpath ".
When the ratio between front and rear layer B ion cluster footpath of electrolysis is more than 0.83, the voltage rise in electrolysis can be suppressed, suppressed
It is electrolysed the reduction of performance.As its reason, it is believed that it is due to that layer B ion cluster footpath before electrolysis does not increase too, can
Suppress being substantially increased for the thickness caused by the moisture content increase of amberplex, but be not limited to this.The front and rear layer B of electrolysis
The ratio between ion cluster footpath when being less than 0.95, the ion selectivity in electrolysis is good.As its reason, it is believed that be due to electrolysis
In layer B ion cluster footpath be contracted to optimum size, but be not limited to this.From the aspect of such, it is electrolysed front and rear layer B's
The ratio between ion cluster footpath is 0.83~0.95.It should be noted that increase can be passed through by being electrolysed the ratio between front and rear layer B ion cluster footpath
The ion cluster footpath of layer B before energization, the ion cluster footpath for reducing the layer B after being powered, reduce the main points such as the ratio and control above-mentioned
Scope.Specifically, for example, the mode such as the treatment temperature handled by raising salt described later to exchange or extension processing time, leads to
The ion cluster footpath of layer B before electricity is tended to increase.
[ion cluster footpath]
Before electrolysis, in the amberplex of present embodiment, layer A ion cluster footpath be preferably 3.0nm~4.5nm,
More preferably 3.2nm~4.0nm, more preferably 3.4nm~3.8nm.In amberplex before electrolysis, layer B from
Submanifold footpath is preferably 2.5nm~4.0nm, more preferably 3.0nm~3.8nm, more preferably 3.2nm~3.6nm.Need
Bright, in the case where layer A is formed by forming different more than 2 layers, ion cluster footpath is their average value.For example, in layer A
In the case of being formed by this 2 layers of layer A-1 and layer A-2, the average value in layer A-1 and layer A-2 ion cluster footpath be preferably 3.0nm~
4.5nm.The ion cluster footpath of layer A and layer B in amberplex before electrolysis within the above range when, the electricity of amberplex
Solution performance and intensity are tended to further improve.That is, when cluster footpath is more than the lower limit of above range, intensity is tended to further carry
It is high;When cluster footpath is less than the higher limit of above range, it is intended to can further suppress the rising of voltage.It should be noted that from
Submanifold footpath is carried out as follows measure:Layer A and layer B are peeled off, after being separated into the monofilm only formed by each layer, by resulting layer A
Film immersion with layer B carries out the survey in ion cluster footpath by small angle X ray scattering (SAXS) in this condition in 25 DEG C of water
It is fixed.It should be noted that in the case that amberplex has coating layer, brush etc. can be utilized to be separated after removing the coating layer
Into the monofilm only formed by each layer, SAXS measure can be imposed as described above in addition.After detailed content is recorded in
In the embodiment stated.
In the amberplex of present embodiment, after the electrolysis of above-mentioned electrolytic condition (1), layer B ion cluster footpath is excellent
Elect 2.0nm~3.3nm, more preferably 2.5nm~3.2nm as.Further, in the amberplex of present embodiment, from
Further improve electrolysis performance and intensity from the aspect of, particularly preferably electrolysis before layer B ion cluster footpath for 2.5nm~
4.0nm and layer B ion cluster footpath after being electrolysed is 2.0nm~3.3nm.
[ion exchange capacity]
In the amberplex of present embodiment, the ion exchange capacity for forming layer A and layer B fluoropolymer is control
One of the factor in ion cluster footpath processed.The ion exchange capacity of fluoropolymer refers to working as the exchange base in every 1g dry resins
Amount, is measured using acid-base titration.The ion exchange capacity for forming layer A fluoropolymer A is preferably 0.8 milliequivalent/g
~1.2 milliequivalents/g, more preferably 0.9 milliequivalent/g~1.1 milliequivalents/g.Form layer B fluoropolymer B ion exchange
Capacity is preferably 0.75 milliequivalent/more than g, more preferably 0.81 milliequivalent/g~0.98 milliequivalent/g.Fluoropolymer from
When sub- exchange capacity is in above range, it is intended to more effectively suppress the electrolysis performance of amberplex and the drop of intensity
It is low.In addition, the ion exchange capacity of the fluoropolymer B by making composition layer B is more than 0.81, it is aqueous in amberplex
Rate increases, thus cluster easily occurs in electrolysis and shrinks.It should be noted that the ion exchange capacity of each layer is bigger, this layer
Ion cluster footpath is more tended to increase;Ion exchange capacity is smaller, and ion cluster footpath is more tended to reduce.In addition, the ion of each layer is handed over
The selection of the monomer for the fluoropolymer that capacity can for example contain by forming in this layer and the content of the monomer are changed to be controlled
System.Specifically, it such as can be controlled by the rate of charge of above-mentioned formula (1)~(3), more specifically, include ion
The content of the monomer represented by formula (2), (3) of exchange base is bigger, and ion exchange capacity is more tended to increase.
[enhancing core]
The amberplex of present embodiment includes enhancing core 3 preferably in film.Enhancing core can strengthen ion friendship
Film strength and dimensional stability are changed, is preferably in the inside of film main body.It is preferably knitting woven with splicing thread to strengthen core
Cloth etc..There is the reason for long-term heat resistance, chemical proofing out of need, the material for strengthening core is preferably to be polymerize by fluorine system
The fiber that thing is formed.Material as enhancing core is not particularly limited, such as can enumerate polytetrafluoroethylene (PTFE) (PTFE), tetrafluoro
Ethene-perfluoroalkyl vinyl ether copolymer (PFA), tetrafluoroethylene-ethylene copolymer (ETFE), hexafluoropropylene (HFP)/tetrafluoroethylene (TFE)
Copolymer, chlorotrifluoroethylene-ethylene copolymer and vinylidene fluoride polymer (PVDF) etc., particularly preferred use is by polytetrafluoroethyl-ne
The fiber that alkene is formed.
As the line footpath of enhancing core, the denier of the danier of preferably 20 daniers~300, more preferably 50 daniers~250
Neil, as weave density (per unit length beating radical), preferably 5 pieces/inch~50 pieces/inch.As enhancing core
Shape, can enumerate and weave cotton cloth, non-woven fabrics or compile cloth etc., the form preferably weaved cotton cloth.In addition, the thickness weaved cotton cloth is preferably 30 μm
~250 μm, more preferably 30 μm~150 μm.
Be not particularly limited to weaving cotton cloth or compiling cloth, for example, using monofilament, multifilament or their yarn, cut film wire etc., weave
Knitted, be knitted using plain weave, leno, cheating that line, which is knitted, crape striped is thin the various weaves such as knits.
In addition, the percent opening for strengthening core is not particularly limited, preferably more than 30%, more preferably more than 50%
Less than 90%.From the electrochemical properties aspect as amberplex, percent opening is preferably more than 30%;In addition, from
Set out in terms of the mechanical strength of film, percent opening is preferably less than 90%.Percent opening refers to the materials such as amberplex intermediate ion
Total (B) for the area that can pass through is represented relative to the ratio of total (A) of the surface area of amberplex with (B)/(A).
(B) refer to not be ion exchanged enhancing core or splicing thread contained by film etc. in amberplex intermediate ion and electrolyte etc.
The area in the region stopped adds up to.The assay method of percent opening is as described below.Shoot amberplex (Coating etc. it
Preceding cation-exchange membrane) surface image, by being obtained above-mentioned (B) in the absence of the area of part of enhancing core.Also, by from
The area of the surface image of proton exchange obtains above-mentioned (A), will be above-mentioned (B) divided by above-mentioned (A), so as to obtain percent opening.
In these various enhancing cores, the enhancing core as particularly preferred mode, such as preferred following manner:Use
By the high intensity, porous flat filament for being cut into banding being made up of PTFE or the 50 height-oriented daniers being made up of PTFE~
The monofilament of 300 daniers, formed by the plain weave structure that weave density is 10 pieces/inch~50 pieces/inch, and then its thickness is 50
μm~100 μm of scope and its percent opening be more than 60%.
And then in weaving cotton cloth, in the manufacturing process of film, in order to prevent strengthening the dislocation of core, generally quilt can be included
Referred to as sacrifice the auxiliary fiber of core.By the way that comprising the sacrifice core, intercommunicating pore 2a, 2b can be formed in amberplex.
Sacrifice core has dissolubility in the manufacturing process of film or under electrolytic environments, and there is no particular limitation as to it,
Use artificial silk, polyethylene terephthalate (PET), cellulose and polyamide etc..In this case the mixed amount of knitting is preferred
To weave cotton cloth or compiling the mass % of the mass %, more preferably 30 mass % of 10 overall mass % of cloth~80~70.
[intercommunicating pore]
The amberplex of present embodiment can have intercommunicating pore 2a, 2b in film.In the present embodiment, intercommunicating pore
Refer to can be formed in cation caused by electrolysis, electrolyte stream hole.By forming intercommunicating pore, caused by electrolysis
Basic ion, the mobility of electrolyte are tended to further improve.The shape of intercommunicating pore is not particularly limited, can be according to aftermentioned
Preparation method turn into intercommunicating pore formation in use sacrifice core shape.
In the present embodiment, intercommunicating pore is preferably according to the anode-side (layer A sides) and cathode side alternately through enhancing core
The mode of (layer B sides) is formed.By as such structure, strengthening part of the cathode side formed with intercommunicating pore of core
In, enhancing core can also be flow to and the cation (such as sodium ion) being transmitted by the electrolyte being filled in intercommunicating pore
The cathode side of material.As a result, the flowing of cation will not be blocked, thus with the electricity that can further reduce amberplex
The tendency of resistance.
[coating]
The amberplex of present embodiment can have in cathode side and anode-side as needed to be used to prevent that gas is attached
The coating layer 6,7.As form coating layer material be not particularly limited, from prevent gas adhere to aspect, preferably
Include inorganic matter.It is not particularly limited as inorganic matter, such as zirconium oxide, titanium oxide etc. can be enumerated.As formation coating layer
Method be not particularly limited, known method can be used.Such as following methods can be enumerated:By the fine of inorganic oxide
Particle is dispersed in binder polymer solution, and resulting dispersion liquid is coated using spraying etc..
[manufacture method of amberplex]
Manufacture present embodiment amberplex when, in order to before being electrolysed in above-mentioned electrolytic condition (1) and it
The ratio between the layer B ion cluster footpath of fluoropolymer with carboxylic acid group that includes afterwards is controlled within the above range, to fluoropolymer
Thing A and the respective ion exchange capacities of fluoropolymer B and the condition of hydrolysis etc. are adjusted.Below to present embodiment
The manufacture method of amberplex is described in detail.
The manufacture method of the amberplex of present embodiment is not particularly limited, preferably comprises the system of following processes
Make method:
1) manufacture can be contained with ion-exchange group or by hydrolyzing to form the ion exchange based precursor of ion-exchange group
The process (manufacturing process of polymer) of fluoropolymer,
2) process (manufacturing process of enhancing core) of the enhancing core woven with victim line is obtained,
3) by with ion-exchange group or can by hydrolyze to form ion-exchange group ion exchange based precursor it is fluorine-containing
Polymer carries out the process (membranization process) of membranization,
4) above-mentioned enhancing core and above-mentioned film are formed into the process of composite membrane (embedment process) by embedment, and
5) process (hydrolyzing process) that composite membrane is hydrolyzed using acid or alkali.
Herein, " ion-exchange group " refers to sulfonic group or carboxylic acid group.
In the amberplex of present embodiment, in above-mentioned operation, such as by polymer manufacturing process 1)
The ion exchange capacity of middle control fluoropolymer and/or the condition that hydrolysis is controlled in hydrolyzing process 5), can adjust electricity
The ratio between front and rear layer B ion cluster footpath of solution.Each operation is illustrated below.
1) process (manufacturing process of polymer)
Form layer A has sulfonic fluoropolymer A for example can be as described above by by the 1st group of monomer and the 2nd
Group monomer copolymerization or the 2nd group of monomer homopolymerization is manufactured.Forming the layer B fluoropolymer B with carboxylic acid group for example can be with
Manufactured as described above by by the 1st group of monomer with the 3rd group of monomer copolymerization or by the 3rd group of monomer homopolymerization.Do not have to polymerization
It is particularly limited to, such as polymerization usually used in ethylene fluoride, the particularly polymerization of tetrafluoroethene can be used.
Fluoropolymer can for example be obtained by non-aqueous method.In non-aqueous method, such as perfluoroparaffin, chlorine fluorine can be used
The atent solvents such as hydrocarbon, it is 0 in temperature in the presence of the radical polymerization initiator such as perfluorocarbon peroxide or azo-compound
DEG C~200 DEG C, pressure be 0.1MPa~20MPa under conditions of carry out polymerisation.
In the manufacture of fluoropolymer, the species and its ratio of the combination to above-mentioned monomer are not particularly limited, can be with
Determined according to the species for the functional group for wishing to assign resulting fluorine-containing based polymer and amount etc..
In the present embodiment, in order to control the ion exchange capacity of fluoropolymer, the fluorine-containing of each layer can formed
The mixing ratio of starting monomer is adjusted in the manufacture of polymer.
Form layer A there is sulfonic fluoropolymer A preferably will for example be carried out by the monomer of above-mentioned formula (2) expression
It polymerize come the monomer that manufactures or will be represented by above-mentioned formula (1) and the monomer represented by above-mentioned formula (2) by following mol ratios
It is copolymerized to manufacture.
The monomer represented by above-mentioned formula (1):Monomer=4 represented by above-mentioned formula (2):1~7:1.
The monomer that form the layer B fluoropolymer B with carboxylic acid group preferably will for example be represented by above-mentioned formula (3) is carried out
It polymerize come the monomer that manufactures or will be represented by above-mentioned formula (1) and the monomer represented by above-mentioned formula (3) by following mol ratios
It is copolymerized to manufacture.
The monomer represented by above-mentioned formula (1):Monomer=6 represented by above-mentioned formula (3):1~9:1.
2) process (manufacturing process of enhancing core)
From the aspect of further raising film strength, the amberplex of present embodiment is embedded to increasing preferably in film
Strong core.When preparing the amberplex with intercommunicating pore, victim line is also woven into together in enhancing core.Now sacrificial
The mixed amount of knitting of domestic animal line is preferably to strengthen the matter of the mass %, more preferably 30 mass % of 10 overall mass % of core~80~70
Measure %.As victim line, also preferably with 20 daniers~50 rugosity of the danier, polyethylene that is formed by monofilament or multifilament
Alcohol etc..
3) process (membranization process)
It is not particularly limited for the method that the fluoropolymer obtained by above-mentioned 1) process is carried out to membranization, preferably uses
Extruder.As the method for membranization, following method can be enumerated.
When layer A and layer B respectively constitute individual layer, it can enumerate and each enter fluoropolymer A, fluoropolymer B respectively
The method of row membranization.
When layer A has 2 Rotating fields formed by layer A-1 and layer A-2, following methods can be enumerated:By fluoropolymer
Composite membrane is made by coextrusion in A-2 and fluoropolymer B, the method that fluoropolymer A-1 is separately individually carried out to membranization;Or
Composite membrane is made by coextrusion in fluoropolymer A-1 and fluoropolymer A-2 by person, separately individually enters fluoropolymer B
The method of row membranization.Among these, if fluoropolymer A-2 and fluoropolymer B is coextruded, interface is favorably improved
Adhesive strength, thus preferably.
4) process (embedment process)
In process is embedded to, preferably by the enhancing core obtained by above-mentioned 2) process and the film obtained by above-mentioned 3) process
It is embedded on cylinder after heating.On cylinder, containing for each layer is being formed across the heat resistance separate paper with gas permeability
Fluoropolymer removes the air of each interlayer by depressurizing while being embedded at a temperature of melting, and carries out integration, so as to
Obtain composite membrane.It is not particularly limited as cylinder, such as can enumerates with heating source and vacuum source and have on its surface
The cylinder of a large amount of micropores.
As order when core and film carry out lamination will be strengthened, following method can be enumerated according to above-mentioned 3) process.
When layer A and layer B respectively constitute individual layer, lamination separate paper, layer A film, the enhancing successively on cylinder can be enumerated
Core, layer B film method.
When layer A has 2 Rotating fields formed by layer A-1 and layer A-2, it can enumerate on cylinder that lamination is anti-sticking successively
Paper, layer A-1 film, enhancing core, layer A-2 and layer B composite membrane method;Or lamination separate paper, layer successively on cylinder
A-1 and layer A-2 composite membrane, enhancing core, layer B method.
In addition, when setting convex portion on the film surface of the amberplex of present embodiment, can be carried out by using advance
The separate paper of Embossing processing and the convex portion being made up of the polymer melted is formed in embedment.
5) process (hydrolyzing process)
The composite membrane obtained in above-mentioned 4) process is hydrolyzed using acid or alkali.In the hydrolyzing process, it can pass through
Change hydrolysising condition, such as solution composition, hydrolysis temperature, the time control the ratio between front and rear layer B ion cluster footpath of electrolysis.
In the manufacture of the amberplex of present embodiment, during hydrolysis, preferably for example in the potassium hydroxide of the equivalent (N) of 2.5 equivalents~4.0
(KOH) and 20 mass %~40 carried out in mass % DMSO (dimethyl sulfoxide (DMSO)) aqueous solution in 40 DEG C~90 DEG C 10 minutes~
24 hours.Thereafter equivalent (N) sodium hydroxide (NaOH) solution of 0.5 equivalent~0.7 is used preferably under conditions of 50 DEG C~95 DEG C
Carry out salt exchange processing.It should be noted that rise from the voltage more effectively prevented caused by thickness excessively increases
From the aspect of, when the treatment temperature in above-mentioned salt exchange processing is more than 70 DEG C, processing time is preferably smaller than 2 hours.
It should be noted that ion cluster footpath can be carried out by the composition of the solution to process is hydrolyzed, temperature, time etc.
Change to control.For example, in the case where wanting increase ion cluster footpath, can be by reducing KOH concentration, improving DMSO concentration, increasing
High hydrolysis temperature or extend hydrolysis time and reach.By controlling the ion cluster footpath of each layer, can also control before and after being electrolysed
Layer B the ratio between ion cluster footpath, the cluster footpath of the layer B after electrolysis can be made than significantly reducing before electrolysis.Specifically, for example, with
When the mode in the ion cluster footpath of the layer B before increase electrolysis is controlled, it is electrolysed the ratio between front and rear layer B ion cluster footpath and reduces.Separately
Outside, can also after hydrolyzing film surface set coating layer.
[electrolytic cell]
The electrolytic cell of present embodiment possesses the amberplex of present embodiment.Present embodiment is shown in Fig. 2
The schematic diagram of one of electrolytic cell.Electrolytic cell 13 at least possesses anode 11, negative electrode 12 and configured between the anode and the cathode
The amberplex 1 of present embodiment.Electrolytic cell can be used in various electrolysis, below, as representative examples, to for alkali metal chlorine
Situation in the electrolysis of the compound aqueous solution illustrates.
Electrolytic condition is not particularly limited, carried out using known condition.For example, 2.5 can be supplied to anode chamber
The aqueous alkali metal chloride of the equivalent (N) of equivalent~5.5, water or diluted alkali metal hydroxide water are supplied to cathode chamber
Solution, electrolysis temperature be 50 DEG C~120 DEG C, current density 0.5kA/m2~10kA/m2Under conditions of be electrolysed.
The electrolytic cell of present embodiment is constructed without being particularly limited to, such as can be that acyclic type can also be multipole
Formula.It is not particularly limited as the material for forming electrolytic cell, for example, the material as anode chamber, preferred pair alkali metal chloride
Has indefatigable titanium etc. with chlorine, as the material of cathode chamber, preferred pair alkali metal hydroxide and hydrogen have indefatigable nickel etc..Close
In the configuration of electrode, appropriate interval can be set to be configured between amberplex and anode, anode can also be made
Configured with amberplex contact.In addition, negative electrode generally sets appropriate interval to be configured with amberplex,
But can also be the electrolytic cell (zero pole span formula electrolytic cell) of the contact-type without the interval.
Embodiment
Present embodiment is explained by the following examples.It should be noted that present embodiment is not limited to
Following examples.
Each assay method in embodiment and comparative example is as described below.
[assay method in ion cluster footpath]
Ion cluster footpath is measured by small angle X ray scattering (SAXS).In SAXS measure, have in amberplex
In the case of coating layer, after coating layer is removed using brush, layer A and layer B is peeled off, for the individual layer only formed by each layer
Film, after being immersed in 25 DEG C of water, it is measured in this condition.SAXS measure uses Rigaku SAXS devices Nano
Viewer.For small angular zone, distance is 841mm, uses PILATUS100K as detector between sample-detector, for wide
Angular zone, between sample-detector distance be 75mm, detector be measured using imaging plate, two curves are merged, so as to
To angle of scattering be 0.1 °<Angle of scattering (2 θ)<The scattering data of 30 ° of scope.Sample is measured with 7 overlapping states,
Time for exposure is 15 minutes in small angular zone, wide-angle area test.In the case where obtaining data using two-dimensional detector,
By the annulus rational gimmick such as averagely by data one-dimensional.For resulting SAXS curves, the dark current of examinations device
Correction etc. comes the correction of self-detector, correction (the blank ware scattering school for being scattered as caused by the material beyond sample
Just).In the case where influence (influence of hangover) of the X-ray beam shape for SAXS curves is big, also carry out being directed to X ray light
The correction (going to trail) of harness shape.For the one-dimensional SAXS curves so obtained, originally directly recorded according to bridge Ben Kangbo, slope, meal Shima show
Method described in height of tree molecule collection of thesis vol.63No.3pp.166 2006 obtains ion cluster footpath.I.e., it is assumed that ion clustering architecture
Represented by the rigid body ball of the core-shell type with particle diameter distribution, it is bent for actual measurement SAXS using the theoretical scattering formula based on the model
The SAXS curves that the scattering from ion cluster of line scatters angular zone for mastery are fitted, so as to obtain mean cluster diameter
(ion cluster footpath), ion cluster number density.In the model, the part of core turns into ion cluster equivalent to ion cluster, the diameter of core
Footpath.It should be noted that shell is imaginary, it is believed that the electron density of shell is identical with body portion.In addition, shell is set herein
Thickness is 0.25nm.Shown in the theoretical scattering formula of the model used in fitting such as following formula (A).In addition, fit range is set as 1.4
6.7 ° of 2 θ < of <.
[number 1]
In formula,
Q=4 π sin θs/λ
α=(1+2 η)2/(1-η)4
The η (1+ η/2) of β=- 62/(1-η)4
The η (1+2 η) of γ=1/22/(1-η)4
A=2qa2
a2=a0+t
In above-mentioned formula, C represents constant, and N represents cluster number density, and η is represented core, i.e. ion cluster part and the vacation around it
The shell thought is assumed to its volume fraction during rigid body ball, and θ represents Bragg angle, and λ represents X-ray wavelength used, and t represents that shell is thick
Degree, a0Average ion cluster radius is represented, Γ (x) represents gamma function, and σ represents the standard deviation of ion cluster radius (nuclear radius).P
(a) nuclear radius a distribution function is represented, a volume distributed median is according to Schultz-Zimm distribution ps (a) herein.M is to represent to be distributed
Parameter.Ib (q) represents the scattering of excessive water during from measure, represents to include the backscatter of thermal diffusion scattering, false herein
It is set to constant.In fitting, among above-mentioned parameter, by N, η, a0, σ, Ib (q) be set to variable element.It should be noted that this
In specification, ion cluster footpath refers to the average diameter (2a of ion cluster0)。
[assay method of the thickness of each layer after hydrolyzing process]
The layer A-1 sides or layer B lateral cross direction of amberplex after hydrolyzing process, before electrolysis are with about 100 μm
Width is cut, and section is surveyed thickness using light microscope towards top in the state of aqueous.Now, the part cut
For the center section (valley) of adjacent enhancing core, if representing in Fig. 1, it is measured in resulting sectional view
Position is the center section of adjacent enhancing core 3, by the direction from (α) towards (β) as thickness direction, determines layer A and layer B
Thickness.
[electrolysis performance evaluation]
As electrolytic cell, zero polar distance electrolytic bath obtained from the composition of the electrolytic cell 13 shown in Fig. 2 is changed as follows is used.
That is, the electrolytic cell prepared be make amberplex 1 in electrolytic cell 13 and the position relationship of anode 11 and negative electrode 12 according to from
State (the shape of so-called " zero pole span " that the state and amberplex 1 that proton exchange 1 connects with anode 11 connect with negative electrode 12
State) changed obtained from.Using zero polar distance electrolytic bath, it is electrolysed under conditions of following, based on decomposition voltage, electricity
Sodium chloride amount evaluation electrolysis performance in stream efficiency, the sodium hydroxide generated.It should be noted that amberplex is in negative electrode
When connecting when connecting with the whole electrode surface of anode and in the certain point of electrode surface, the state of zero pole span is accordingly to be regarded as.
In anode-side while being adjusted according to the concentration of sodium chloride for the concentration of 3.5 equivalents (N) while supply salt solution, one
While the naoh concentration of cathode side is maintained at 10.8 equivalents (N) while supply water.The temperature of salt solution is set as 85 DEG C, with
6kA/m2Current density, electrolytic cell cathode side hydraulic pressure than the hydraulic pressure of anode-side it is high 5.3kPa under conditions of carry out electricity
Solution.
The concentration of the sodium chloride contained in the sodium hydroxide of 7 days is electrolysed by JIS standard Ks 1200-3-1 method measure.To
Nitric acid is added in electrolytically generated sodium hydroxide to be neutralized, and is added ferric sulfate (III) ammonium salt solution, mercuric thiocyanate (II), is made molten
Liquid develops the color.The solution is counted using UV and carries out spectrophotometric analysis, so as to determine the sodium chloride concentration in sodium hydroxide, obtains the
The measured value of 7 days is as the sodium chloride concentration in sodium hydroxide.UV meters use JASCO V-630Spetrophotometer.
In addition, current efficiency is obtained as follows:Quality, the concentration of the generated sodium hydroxide of measure, will give birth in certain time
Into sodium hydroxide molal quantity divided by the electric current flowed therebetween electronics molal quantity, so as to obtain current efficiency.
[strength test]
As strength test, using the amberplex after hydrolysis (before electrolysis), according to JIS K 6732 stretch by force
The measure of degree and tensile elongation.
[embodiment 1]
As fluoropolymer A-1, the monomer (X that will be represented by following formulas (1)1=F, X2=F) and by following formulas
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.It should be noted that ion exchange capacity is confirmed using acid-base titration.In following embodiment and comparative example
In similarly confirm ion exchange capacity.
CF2=CX1X2 (1)
CF2=CF- (OCF2CYF)a-O-(CF2)b-SO2F (2)
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.99 milli
Amount/g polymer.
As forming layer B fluoropolymer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and under
State monomer (c=1, d=2, Y=CF of formula (3) expression3, R=CH3) with mol ratio 7.5:1 copolymerization, has obtained ion exchange appearance
Measure as 0.89 milliequivalent/g polymer.
CF2=CF- (OCF2CYF)c-O-(CF2)d-COOR (3)
It should be noted that on fluoropolymer A (A-1, A-2), in more detail, gathered by solution as shown below
Close to make.
First, CF is put into stainless steel 20L autoclaves2=CFOCF2CF(CF3)O(CF2)2COOCH3And HFC-43-
10mee solution, after fully carrying out nitrogen displacement in container, further utilize CF2=CF2(TFE) replace, carry out heating until
Temperature stabilization in container is pressurizeed at 35 DEG C using TFE.
Next, add the (CF as polymerization initiator3CF2CF2COO)25%HFC43-10mee solution, trigger anti-
Should.Now, the methanol as chain-transferring agent is added.Stirred at 35 DEG C while intermittently supplying TFE, while on the way add
Methanol, make the reduction of TFE pressure, stop polymerization at the time of ormal weight TFE has been supplied.After unreacted TFE is discharged to outside system,
Methanol is added into resulting polymer fluid, is isolated fluorine-containing based polymer cohesion.After being further dried, polymer is obtained
A.Resulting fluorine-containing based polymer is subjected to pellet using double screw extruder.
In addition, for fluoropolymer B, CF is put into2=CFOCF2CF(CF3)O(CF2)2SO2F replaces CF2=
CFOCF2CF(CF3)O(CF2)2COOCH3, without using chain-transferring agent, on the way it is added without methanol and adds (CF3CF2CF2COO)2
5%HFC43-10mee solution, utilize obtain fluoropolymer B with polymer A identical methods in addition.Following
Fluoropolymer A and B pellet is similarly obtained in embodiment and comparative example.
For resulting fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion T
The device of mould and hauling machine is coextruded, and has obtained 2 tunics (a1) that thickness is 93 μm.The section of the film (a1) is utilized
Observation by light microscope, the thickness that resultant layer A-2 thickness is 80 μm, layer B is 13 μm.It should be noted that layer A-2 and layer B
Made a distinction by applying polarised light.In addition, the monofilm (b1) for the layer A-1 that thickness is 20 μm is obtained using individual layer T moulds.
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b1), enhancing core, 2 tunics (a1), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.
As enhancing core, prepare to polytetrafluoroethylene (PTFE) (PTFE) make 100 daniers flat filament carry out 900 times/m twisting and
Manufactured thread;Warp as auxiliary fiber (victim line) prepares the poly terephthalic acid second two of 30 daniers, 6 fibrils
Alcohol ester (PET) carries out the line that 200 times/m twisting forms;Prepare to carry out on the PET lines of 35 daniers, 8 fibrils as parallel
These lines according to PTFE lines are 24 pieces/inch by the line that forms of 10 times/m twisting, victim line relative to 64 that PTFE is 4 times/
The mode of inch interacts arrangement and carries out plain weave, has obtained thickness and be 100 μm weaving cotton cloth.Resulting is weaved cotton cloth using after heating
Metallic roll is crimped, and the thickness weaved cotton cloth is adjusted into 70 μm.Now, only the percent opening of PTFE lines is 75%.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 80 DEG C temperature hydrolyze
0.5 hour, carry out salt exchange in 1 hour using 0.6 equivalent (N) NaOH solution under conditions of 50 DEG C thereafter and handle.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that primary particle size is 1 μm is added into the solution, utilizes ball mill
It is dispersed, obtain suspension.The ion that the suspension is coated on after above-mentioned hydrolysis and salt exchange processing using spray-on process is handed over
The two sides of film is changed, makes its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.91.Measurement result is listed in table 1.
[embodiment 2]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer that will be represented by above-mentioned formula (1) and by above-mentioned formula (2) (a=1, b=2,
Y=CF3) represent monomer with mol ratio 5.7:1 copolymerization, the polymer that ion exchange capacity is 0.99 milliequivalent/g is obtained.
As forming layer B fluoropolymer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by upper
State monomer (c=1, d=2, Y=CF of formula (3) expression3, R=CH3) with mol ratio 7.5:1 copolymerization, has obtained ion exchange appearance
Measure as 0.89 milliequivalent/g polymer.
For resulting fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion T
The device of mould and hauling machine is coextruded, and has obtained 2 tunics (a2) that thickness is 93 μm.The section of the film is utilized into optics
Micro- sem observation, the thickness that resultant layer A-2 thickness is 80 μm, layer B is 13 μm.In addition, having obtained thickness using individual layer T moulds and being
20 μm of layer A-1 monofilm (b2).
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b2), enhancing core, 2 tunics (a2), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Used and the phase of embodiment 1 as enhancing core
Same material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 50 DEG C temperature hydrolyze
24 hours, carry out salt exchange in 0.5 hour using 0.6 equivalent (N) NaOH solution under conditions of 90 DEG C thereafter and handle.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that primary particle size is 1 μm is added into the solution, utilizes ball mill
It is dispersed, obtain suspension.The ion that the suspension is coated on after above-mentioned hydrolysis and salt exchange processing using spray-on process is handed over
The two sides of film is changed, makes its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.93.Measurement result is listed in table 1.
[embodiment 3]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.99 milli
Amount/g polymer.
As the fluoropolymer B for forming fluoropolymer layer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2
=F) and by above-mentioned formula (3) represent monomer (c=1, d=2, Y=CF3, R=CH3) with mol ratio 7.3:1 copolymerization, is obtained
Ion exchange capacity is 0.91 milliequivalent/g polymer.
For fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion with T moulds and lead
The device for drawing machine is coextruded, and has obtained 2 tunics (a3) that thickness is 93 μm.The section of the film is seen using light microscope
Examine, as a result fluoropolymer layer A-2 thickness be 80 μm, fluoropolymer layer B thickness be 13 μm.In addition, utilize individual layer T moulds
The monofilm (b3) for the fluoropolymer layer A-1 that thickness is 20 μm is obtained.
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b3), enhancing core, 2 tunics (a3), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Used and the phase of embodiment 1 as enhancing core
Same material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 50 DEG C temperature hydrolyze
24 hours, carry out salt exchange in 1 hour using 0.6 equivalent (N) NaOH solution under conditions of 95 DEG C thereafter and handle.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that primary particle size is 1 μm is added into the solution, utilizes ball mill
It is dispersed, obtain suspension.The ion that the suspension is coated on after above-mentioned hydrolysis and salt exchange processing using spray-on process is handed over
The two sides of film is changed, makes its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.86.Measurement result is listed in table 1.
[embodiment 4]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 6:1 copolymerization, ion exchange capacity is obtained and has worked as 0.95 milli
Amount/g polymer.
As the fluoropolymer B for forming fluoropolymer layer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2
=F) and by above-mentioned formula (3) represent monomer (c=1, d=2, Y=CF3, R=CH3) with mol ratio 8:1 copolymerization, obtained from
Sub- exchange capacity is 0.85 milliequivalent/g polymer.
For fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion with T moulds and lead
The device for drawing machine is coextruded, and has obtained 2 tunics (a4) that thickness is 100 μm.The section of the film is utilized into light microscope
Observation, as a result fluoropolymer layer A-2 thickness be 85 μm, fluoropolymer layer B thickness be 15 μm.In addition, utilize individual layer T
Mould has obtained the monofilm (b4) for the fluoropolymer layer A-1 that thickness is 25 μm.
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b4), enhancing core, 2 tunics (a4), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Used and the phase of embodiment 1 as enhancing core
Same material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 80 DEG C temperature hydrolyze
0.5 hour, carry out salt exchange in 1 hour using 0.6 equivalent (N) NaOH solution under conditions of 50 DEG C thereafter and handle.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that primary particle size is 1 μm is added into the solution, utilizes ball mill
It is dispersed, obtain suspension.The ion that the suspension is coated on after above-mentioned hydrolysis and salt exchange processing using spray-on process is handed over
The two sides of film is changed, makes its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.93.Measurement result is listed in table 1.
[embodiment 5]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.99 milli
Amount/g polymer.
As forming layer B fluoropolymer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by upper
State monomer (c=1, d=2, Y=CF of formula (3) expression3, R=CH3) with mol ratio 7.5:1 copolymerization, has obtained ion exchange appearance
Measure as 0.89 milliequivalent/g polymer.
For resulting fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion T
The device of mould and hauling machine is coextruded, and has obtained 2 tunics (a1) that thickness is 93 μm.The section of the film (a1) is utilized
Observation by light microscope, the thickness that resultant layer A-2 thickness is 80 μm, layer B is 13 μm.It should be noted that layer A-2 and layer B
Made a distinction by applying polarised light.In addition, the monofilm (b1) for the layer A-1 that thickness is 20 μm is obtained using individual layer T moulds.
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b1), enhancing core, 2 tunics (a1), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.
As enhancing core, the flat filament that 100 daniers will be made to polytetrafluoroethylene (PTFE) (PTFE) carries out 900 times/m twisting and made
Into thread plain weave is carried out in the way of 24 pieces/inch, obtained thickness and be 100 μm weaving cotton cloth.Resulting is weaved cotton cloth
Crimped using the metallic roll after heating, the thickness weaved cotton cloth is adjusted to 70 μm.Now, the percent opening of only PTFE silks is
75%.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 80 DEG C temperature hydrolyze
0.5 hour, carry out salt exchange in 1 hour using 0.6 equivalent (N) NaOH solution under conditions of 50 DEG C thereafter and handle.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that primary particle size is 1 μm is added into the solution, utilizes ball mill
It is dispersed, obtain suspension.The ion that the suspension is coated on after above-mentioned hydrolysis and salt exchange processing using spray-on process is handed over
The two sides of film is changed, makes its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.95.Measurement result is listed in table 1.
[comparative example 1]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.99 milli
Amount/g polymer.
As the fluoropolymer B for forming fluoropolymer layer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2
=F) and by above-mentioned formula (3) represent monomer (c=1, d=2, Y=CF3, R=CH3) with mol ratio 8.5:1 copolymerization, is obtained
Ion exchange capacity is 0.80 milliequivalent/g polymer.
For resulting fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion T
The device of mould and hauling machine is coextruded, and has obtained 2 tunics (a5) that thickness is 93 μm.The section of the film is utilized into optics
Micro- sem observation, the thickness that resultant layer A-2 thickness is 80 μm, layer B is 13 μm.In addition, having obtained thickness using individual layer T moulds and being
20 μm of layer A-1 monofilm (b5).
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b5), enhancing core, 2 tunics (a5), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Used and the phase of embodiment 1 as enhancing core
Same material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 80 DEG C temperature hydrolyze
0.5 hour, carry out salt exchange in 1 hour using 0.6 equivalent (N) NaOH solution under conditions of 50 DEG C thereafter and handle.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that primary particle size is 1 μm is added into the solution, utilizes ball mill
It is dispersed, obtain suspension.The ion that the suspension is coated on after above-mentioned hydrolysis and salt exchange processing using spray-on process is handed over
The two sides of film is changed, makes its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.Configured in fluoropolymer layer A towards anode-side above-mentioned
In electrolytic cell, in 6kA/m2Current density under, temperature is set in 85 DEG C, be electrolysed within 7 days.The project of measure is electrolysis electricity
Sodium chloride amount in pressure, current efficiency, the sodium hydroxide that is generated, start the measured value of latter 7th day with electrolysis respectively and evaluate electricity
Solve performance.Now, the value in (the ion cluster footpath of the layer B after electrolysis)/(the ion cluster footpath of the layer B before electrolysis) is 0.98.Electric current is imitated
Rate is measured using method same as Example 1.
[comparative example 2]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.99 milli
Amount/g polymer.
As the fluoropolymer B for forming fluoropolymer layer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2
=F) and by above-mentioned formula (3) represent monomer (c=1, d=2, Y=CF3, R=CH3) with mol ratio 7.5:1 copolymerization, is obtained
Ion exchange capacity is 0.89 milliequivalent/g polymer.
For resulting fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion T
The device of mould and hauling machine is coextruded, and has obtained 2 tunics (a6) that thickness is 93 μm.The section of the film is utilized into optics
Micro- sem observation, the thickness that resultant layer A-2 thickness is 80 μm, layer B is 13 μm.In addition, having obtained thickness using individual layer T moulds and being
20 μm of layer A-1 monofilm (b6).
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b6), enhancing core, 2 tunics (a6), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Used and the phase of embodiment 1 as enhancing core
Same material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 50 DEG C temperature hydrolyze
0.5 hour, carry out salt exchange in 5 hours using 0.6 equivalent (N) NaOH solution under conditions of 95 DEG C thereafter and handle.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that primary particle size is 1 μm is added into the solution, utilizes ball mill
It is dispersed, obtain suspension.The ion that the suspension is coated on after above-mentioned hydrolysis and salt exchange processing using spray-on process is handed over
The two sides of film is changed, makes its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.77.Measurement result is listed in table 1.
[comparative example 3]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.98 milli
Amount/g polymer.
As forming layer B fluoropolymer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by upper
State monomer (c=1, d=2, Y=CF of formula (3) expression3, R=CH3) with mol ratio 8.5:1 copolymerization, has obtained ion exchange appearance
Measure as 0.80 milliequivalent/g polymer.
Prepare fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion with T moulds and lead
The device for drawing machine is coextruded, and has obtained 2 tunics (a5) that thickness is 93 μm.The section of the film is seen using light microscope
Examine, as a result fluoropolymer layer A-2 thickness is that 75 μm, layer B thickness is 15 μm.In addition, thickness is obtained using individual layer T moulds
For 20 μm of layer A-1 monofilm (b5).
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b5), enhancing core, 2 tunics (a5), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Enhancing core uses same as Example 1
Material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 75 DEG C temperature hydrolyze
0.75 hour, carry out salt exchange processing using 0.6 equivalent (N) NaOH solution under conditions of 85 DEG C thereafter.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that average primary particle diameter is 1 μm is added into the solution, utilizes ball
Grinding machine is dispersed, obtains suspension.By the suspension using spray-on process be coated on above-mentioned hydrolysis and salt exchange processing after from
The two sides of proton exchange, make its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.98.Measurement result is listed in table 1.
[comparative example 4]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.98 milli
Amount/g polymer.
As forming layer B fluoropolymer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by upper
State monomer (c=1, d=2, Y=CF of formula (3) expression3, R=CH3) with mol ratio 8.5:1 copolymerization, has obtained ion exchange appearance
Measure as 0.80 milliequivalent/g polymer.
Prepare fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion with T moulds and lead
The device for drawing machine is coextruded, and has obtained 2 tunics (a5) that thickness is 93 μm.The section of the film is seen using light microscope
Examine, as a result fluoropolymer layer A-2 thickness is that 75 μm, layer B thickness is 15 μm.In addition, thickness is obtained using individual layer T moulds
For 20 μm of layer A-1 monofilm (b5).
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b5), enhancing core, 2 tunics (a5), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Enhancing core uses same as Example 1
Material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 90 DEG C temperature hydrolyze
0.75 hour, carry out salt exchange processing using 0.6 equivalent (N) NaOH solution under conditions of 85 DEG C thereafter.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that average primary particle diameter is 1 μm is added into the solution, utilizes ball
Grinding machine is dispersed, obtains suspension.By the suspension using spray-on process be coated on above-mentioned hydrolysis and salt exchange processing after from
The two sides of proton exchange, make its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.97.Measurement result is listed in table 1.
[comparative example 5]
As fluoropolymer A-1, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5:1 copolymerization, ion exchange capacity is obtained and has worked as 1.05 millis
Amount/g polymer.
As fluoropolymer A-2, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by above-mentioned formula
(2) monomer (a=1, b=2, Y=CF represented3) with mol ratio 5.7:1 copolymerization, ion exchange capacity is obtained and has worked as 0.99 milli
Amount/g polymer.
As forming layer B fluoropolymer B, the monomer (X that will be represented by above-mentioned formula (1)1=F, X2=F) and by upper
State monomer (c=1, d=2, Y=CF of formula (3) expression3, R=CH3) with mol ratio 7.5:1 copolymerization, has obtained ion exchange appearance
Measure as 0.89 milliequivalent/g polymer.
Prepare fluoropolymer A-2 and fluoropolymer B, using possessing 2 extruders, 2 layers of coextrusion with T moulds and lead
The device for drawing machine is coextruded, and has obtained 2 tunics (a5) that thickness is 105 μm.The section of the film is utilized into light microscope
Observation, as a result fluoropolymer layer A-2 thickness is that 80 μm, layer B thickness is 25 μm.In addition, thickness is obtained using individual layer T moulds
Spend the monofilm (b5) of the layer A-1 for 20 μm.
Internally with the cylinder of heating source and vacuum source, surface with a large amount of micropores in order lamination with ventilative
Property heat-resisting separate paper, monofilm (b5), enhancing core, 2 tunics (a5), under 230 DEG C of temperature and -650mmHg decompression
The air of each storeroom is excluded while carrying out integration, has obtained composite membrane.Enhancing core uses same as Example 1
Material.
By the composite membrane containing 30 mass %DMSO, 4.0 equivalents (N) KOH the aqueous solution in 80 DEG C temperature hydrolyze
0.5 hour, carry out salt exchange processing using 0.6 equivalent (N) NaOH solution under conditions of 50 DEG C thereafter.
Dissolved in water and the mixed solution of the mass parts of ethanol 50,/50 20 mass % fluorine system polymer (its be ion hand over
Change the CF that capacity is 1.0 milliequivalents/g2=CF2With CF2=CFOCF2CF(CF3)O(CF2)3SO2The tool that F copolymer hydrolysis forms
There is sulfonic fluorine system polymer).The mass % of zirconium oxide 40 that average primary particle diameter is 1 μm is added into the solution, utilizes ball
Grinding machine is dispersed, obtains suspension.By the suspension using spray-on process be coated on above-mentioned hydrolysis and salt exchange processing after from
The two sides of proton exchange, make its drying, so as to form coating layer.
It is electrolysed for the amberplex as above obtained.(the ion cluster footpath of the layer B after electrolysis)/(layer B before electrolysis
Ion cluster footpath) value be 0.97.Measurement result is listed in table 1.
Composition and characteristic by above-described embodiment and the amberplex of comparative example etc. are listed in table 1.
[table 1]
The electrolysis of the amberplex of embodiment 1~4 is functional, and the intensity of tensile strength and tensile elongation is commented
The result of valency also show can be substantially resistant to the value being electrolysed.
On the other hand, for the amberplex of comparative example 1, although the result of intensity evaluation is good, electrolysis electricity
Pressure is higher than embodiment 1~4.
For the amberplex of comparative example 2, although the result of intensity evaluation is good, decomposition voltage has to increase very much
It is high.
For the amberplex of comparative example 3~4, although the result of intensity evaluation is good, decomposition voltage is higher than
Embodiment 1~4.
For the amberplex of comparative example 5, although the result of intensity evaluation is good, decomposition voltage is higher than implementation
Example 1~4.
The Japanese patent application (Japanese Patent Application 2015-101292) that the application was submitted based on May 18th, 2015, with ginseng
Its content is introduced this specification by the form examined.
Industrial applicibility
The amberplex of the present invention can suitably be applied in the field of alkali chloride electrolysis.
The explanation of symbol
1 amberplex
2a intercommunicating pores
2b intercommunicating pores
3 enhancing cores
4 layers of A
5 layers of B
6 coating layers
7 coating layers
The position of 8 facing layer A anode-side surface
The anode-side of α electrolyte layers
The cathode side of β electrolyte layers
11 anodes
12 negative electrodes
13 electrolytic cells
Claims (7)
1. a kind of amberplex, it has:
Comprising the layer A with sulfonic fluoropolymer and
Layer B comprising the fluoropolymer with carboxylic acid group,
Under following electrolytic conditions be electrolysed after the layer B ion cluster footpath relative to the layer B before the electrolysis ion
The ratio in cluster footpath, i.e. (the ion cluster footpath of the layer B after the electrolysis)/(the ion cluster footpath of the layer B before the electrolysis) be 0.83~
0.95,
The electrolytic condition is:
In zero polar distance electrolytic bath, temperature be 85 DEG C, current density 6kA/m2Under conditions of carry out 7 days be electrolysed, zero pole
Away from electrolytic cell, it is being fed with the anode chamber of the sodium-chloride water solution of 3.5 equivalents (N) and is being fed with 10.8 equivalents (N) hydrogen-oxygen
The amberplex is configured between the cathode chamber of change sodium water solution.
2. amberplex as claimed in claim 1, wherein,
The ion cluster footpath of layer B before the electrolysis is 2.5nm~4.0nm,
The ion cluster footpath of layer B after the electrolysis is 2.0nm~3.3nm.
3. amberplex as claimed in claim 1 or 2, wherein, before the electrolysis, the thickness of the layer A and the layer B
Thickness add up to more than 55 μm.
4. such as amberplex according to any one of claims 1 to 3, wherein, the ion cluster footpath of the layer A before the electrolysis is
3.0nm~4.5nm.
5. such as amberplex according to any one of claims 1 to 4, wherein,
The thickness of layer A before the electrolysis is 50 μm~180 μm,
The thickness of layer B before the electrolysis is 5 μm~20 μm.
6. such as amberplex according to any one of claims 1 to 5, wherein,
The layer A includes the polymer of the compound represented by following formula (2),
The layer B includes the polymer of the compound represented by following formula (3),
CF2=CF- (OCF2CYF)a-O-(CF2)b-SO2F (2)
In formula (2), a represents 0~2 integer, and b represents 1~4 integer, Y expression-F or-CF3;
CF2=CF- (OCF2CYF)c-O-(CF2)d-COOR (3)
In formula (3), c represents 0~2 integer, and d represents 1~4 integer, Y expression-F or-CF3, R expressions-CH3、-C2H5Or-
C3H7。
7. a kind of electrolytic cell, it possesses amberplex according to any one of claims 1 to 6.
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JP6927191B2 (en) * | 2017-12-19 | 2021-08-25 | Agc株式会社 | Manufacture method of ion exchange membrane for alkali chloride electrolysis, ion exchange membrane for alkali chloride electrolysis and alkali chloride electrolyzer |
CN110015748A (en) * | 2018-01-10 | 2019-07-16 | 河南烯碳合成材料有限公司 | Purifier |
WO2019181919A1 (en) * | 2018-03-20 | 2019-09-26 | 旭化成株式会社 | Cation exchange membrane, multilayer membrane, and electrolytic cell |
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TWI609099B (en) | 2017-12-21 |
JPWO2016186083A1 (en) | 2018-03-01 |
US20180126370A1 (en) | 2018-05-10 |
CA2986205A1 (en) | 2016-11-24 |
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